PL84024B1 - - Google Patents

Description

The subject of the invention is a recording medium in formation, especially information, vision and / or sound with a disk-shaped carrier substrate, on which the optical structure is located teller information, being a recording medium is intended to be read with optical radiation and a device for detecting reading the recording medium on which the information it is stored in the optical structure.

In a known record carrier, the information is provided written in analog form, for example in half the form of fields with different values of the ab¬ factor sorption, with these fields arranged into paths write. Such a recording medium is read in optical method, with the reading beam being enters the recording medium on the side of the structure op and comes out of the medium on the opposite side of it side. While passing through the recording media, the pro mien is modulated by the optical structure, according to the information contained therein. Force me the doubled beam is converted into a signal electric by radiation detector.

Because on the recording medium it is recorded large amount of information, details of the optical structure They are very small. If, for example, on a gland to record in the shape of a disc with an outer diameter At a distance of 30 cm, a time-based vision program is saved duration of 45 minutes, the amount of detail is real du 1 ^ im. When reading such a fine structure aurochs are highly affected by dust particles. If these are piles of dust, which are small objects, lie on in their optical structure, they can cover a large number of no neighboring paths and no details on those paths hands, preventing their correct reading no. Moreover, it is possible that, for example, St. while the carrier is being manipulated or placed it is placed in a reading device, on a structure scratches. Because the carrier the recording is intended to be played back in the wa¬ in imperfect conditions, for example indoors residential areas, the optical structure should be make it more or less insensitive to dust and to damage.

It is known to coat the optical structure with an additional transparent layer, which makes the the dust particles cover only part of the radius reading, focused on the optical structure the recording medium. However, such a solution is I want the protective layer to be miniature small but many times greater than the depth of field lens used, such as thickness 100 | xm. In addition, the protective layer must be fine contact with the optical structure to avoid coating standing between the optical structure and the layer protection of local air bubbles.

It remains unchanged in the known device Focusing ability of the focusing lens pro¬ the reading on the optical structure by placing the lens on the airbag on the recording medium. However, it was assumed that 84 02 484 024 3 the thickness of the protective layer is constant throughout outer, or at least that it has no change exceeding the soil sharpness of the lens, which is on the order of 1 ^ m. As a result, the protective layer on must meet strict requirements in terms of accuracy of execution.

The object of the invention is to provide a carrier for writing in which the optical structure is protected to prevent dust particles and damage without the need for a protective layer meeting the strict requirements in terms of do performance.

Information recording medium, in particular information video and / or audio, with a carrier substrate in the shape of the disc on which the structure is placed optical turn corresponding to the formation and the carrier the write is intended for reading it too by means of optical radiation according to the invention The bed is characterized by its optical structure is the radiation reflecting structure, a the substrate of the carrier is transparent to the radiation clear. The surface of the substrate further away from the the optical structure represents both surfaces the input and output surfaces for the profiles of changing the reader. The thickness of the substrate is sufficient to ensure convergence of the beam nanization focused on the optical structure, after passing through said substrate to obtain a hangover larger diameter on the exit side than on the optical structure.

The surface of the optical structure, more reproducible Leaned from the substrate of the carrier, it is equipped with a bottom additional protective layer. Additional thickness a protective layer that absorbs radiation it is small compared to the thickness of the nose substrate nika.

Preferably, the additional layer is a foil attached at least to the edge of the substrate media, or a sheet of paper with glue on one side, possibly a foil of synthetic material it and the layer of glue on one side, or else a layer of lacquer sprayed onto the optical structure.

The optical structure includes coplanar blocks of variable length, separated by real fields, both planes being a fixed distance from each other.

In the extra layer, more on this side away from the optical structure, is situated a second optical structure reflecting radially not in the opposite direction to that the rhyme reflects the radiation first structure op tical. Moreover, the second optical structure is on its own the side farthest from the first structure optical layer is covered with an additional layer of thickness essentially equal to the thickness of the media substrate.

The two optical structures contain the same information video coded in various systems color television.

Device for reading the record carrier, na which the information is stored in the structure the optical source containing the source of radiation emitted detecting reading beam, focusing lens reading beam on optical structure and layout Detection of beam processing radiation reading radiation modulated by 4 optical structure, in electric signal, according to The invention is characterized in that it contains an agent ki for optical signal acquisition, which is a measure of the deviation of the plane of the structure from the plane of focusing the beam from reading, which allows proper adjustment focusing.

The optical structure is read by a ray the reader, which is reflected in the structure of Op through which it is modulated. Radius the reader does not pass through the positive layer that is only needed for security optical structure against damage. Layer this so does not need to meet strict conditions in terms of the accuracy of execution. Does not have to be transparent to radiation and not it must be of constant thickness over its entire surface no. Moreover, it does not have to make exact contact with it cptic structure. This could be, for example, fluid the one attached to the substrate of the recording medium on its edges.

The optical structure can take the form of plane reflecting block and the fields between them, whereby the fields have a reflection coefficient different from that of block reflection factor. Preferably, however, the structure A cptic turn contains blocks and dividers fields having equal reflection coefficients but service erected at different levels.

Optical determination of the deviation between planes the man of the optical structure, and the plane becomes focussed the reading of the reading beam according to the invention bed, allows you to increase the range of variations in the thickness of the carrier substrate, for example up to 300 [xm.

The subject of the invention is described in more detail in an example of the implementation in the drawing where Fig. 1 shows a record carrier without any cover additional layer in top view, Fig. 2 - nose notation index in cross section, fig. 3 - a device for reading the record carrier, and Fig. 4.presents another version of the recording medium, in cross section.

Fig. 1 shows a circular recording medium in top view. This medium contains a structure helical with multiple coaxial paths. Al¬ alternatively, these paths can be guasi - common axial. In Fig. 1, only two adjacent ones are shown tracks 12 and 13. Each track has a structure krenelazowa, the shapes of which are shown in half enlarged section in Fig. 2.

Gaps between apex surfaces mi 3 and 5 and 5 and 7 and the length of the surface the vertexes of individual blocks are different.

Their heights 4, 6 and so on are equal to and is preferably approximately one quarter the wavelength of the radiation applied to od reading. Instead of the perpendicular slopes of the blocks the structure may have possibly smooth transitions between the upper surfaces and the surface and the lower ones.

The substrate 1 of the carrier transmits the radiation of the table can be read. The optical structure is formed on the upper surface of the dial, during when the bottom surface acts both as a 40 45 50 55 6384 024 input surface for non-modulated radius important as well as the starting area for modulated radius. Structure surfaces optics have been made highly reflective due to the fact that after extruding the structure into the base, it is deposited on it by evaporation of the vapor metal, the thickness of which is not critical connection.

Placed on top of the optical structure is the protective layer 10. The sole purpose of the warrant 10 is to protect the optical structure the recording medium from being damaged. So you can use any layer that provides protection against rough handling of the carrier.

As shown in Fig. 2, this layer is thin cza, remote from the optical structure and which is attached to the substrate only at its edge wedzi. A sheet is stuck to the optical structure plastic film with glue on one surface. Alternatively as shown in Fig. 4, a layer is placed on or between the blocks for example, varnish, where -in this case the thickness of the layer is greater than the height of the block cows. Because the optical structure is situated between the substrate 1 and the layer 10, it is capable of to withstand rough handling with-carrier.

Reading beam 15 as depicted here in figure 2 it is phase modulated by the structure krenelazowa. Possibly the top surface 9 the substrate 1 is provided with a reflective structure block radiation and absorbing field radiation, causing the amplification modulation body of the reading beam.

Read disc recording medium shown in Figure 1 it is rotated at 1500 revolutions per minute using - as shown in fig. 3 - driving spindle 24. Reading beam emitted by the radiation source 25 is reflected towards the recording medium by a half transparent mirror 26. Ray 30 passes through through the substrate of the carrier 1 and is reflected from the structure the optical turn, shown as lane 2, in the top the surface of the dial. The lens 21 creates an image the source on the optical structure, the quantity being the bone of this image is in the order of the smallest part structures.

During rotation of the recording medium, the reading radius which is modulated in time according to the sequence for example, blocks in a path. Modulated reading beam 31 passes through a half-way transparent mirror 26 and is assumed by radiation detector 28. At the output of this de¬ tektor produces an electrical signal which corresponds to the information recorded on the recording medium.

Detector 28 is connected to a known circuit electronic intended for processing the detector output signal into an image signal and sound.

Advantages of reading on the radial principle The reflected pattern is illustrated in Fig. 3. All elements optical and electronic processing systems are located on one side of the recording medium, co allows you to easily insert a recording medium in the reading device. Moreover, these items are 6) positioned in such a way as to protect them.

The number of optical elements is thereby reduced shades because some of the elements that meet the dual roles. Reducing the number of items reduces the probability of vibration with respect to each other of these elements.

In addition, the recording medium can be read in a room containing air dust particles, for example in a living room as the dust particles settle on the layer 10 has no effect on the reading, for the reading beam does not pass through these layer. Dust particle deposited on the surface the lower 8 of the substrate can only reduce the no radiation hitting the structure of the op This reduction in intensity is not extreme it is very disadvantageous because the information was registered is valid in digital form. Dust particle not can completely obscure the ray because the ray in the plane of dust particles has a hundred quite large diameter, which results from the fact that that the substrate inherently has a certain thickness, between others for the necessary rigidity.

The recording medium according to the invention may be Preferably used when reading a table Optical focus detection is possible.

A reading device is used for this purpose equipped with an optical-electronic de-system focusing section.

Fig. 4 shows a second embodiment a recording medium according to the invention. Two substrates 1 and 1 ', each of which has an optical structure at one of the surfaces 9 and 9 'are connected by a half power of the intermediate layer 10, to create one team. Such a recording medium is manufactured by methods known from the technology of tar production audio recording media. Structures on the surface 9 and 9 'are read with rays of opposite directions. In this case- 40 is the solution, layer 10 is only needed ko to separate optical structures and need not protect them from external influences.

In the recording medium shown in Fig. 4, both two halves of optical structures are recorded 45 one program.

The transcript carrier shown in Fig. 4 is perfectly written can be implemented with the solution in which information on the same color pictures is written in different systems, in two structures 50 optical accounts of one recording medium. In one from these optical structures you can write a program, for example, according to the color television system PAL, and in the second optical structure according to the signal SFCAM or NTSC system. Then this one Only the information on one recording medium can be used over a large geographical area, despite the use of various playback devices rim and sound. What

Claims (11)

Patent claims 1. An information recording medium, in particular video and / or audio information with a disk-shaped carrier substrate 65 on which an optical structure corresponding to the information is placed, and the record carrier is intended to be read by optical radiation, characterized by in that the optical structure is a radiation reflective structure and the carrier substrate is transparent to radiation, the surface of the substrate farthest from the optical structure is both the input and output surfaces for the read radiation, and the thickness of the substrate is it is sufficient to ensure convergence of the focused radiation on the optical structure after passing through said substrate to obtain a larger diameter on the entry side than on the optical structure. 2. A recording medium according to claim The method of claim 1, wherein the surface of the optical structure further away from. the substrate of the carrier is provided with an additional protective layer. 3. A recording medium according to claim The method of claim 2, characterized in that the thickness of the additional radiation-absorbing protective layer is small compared to the thickness of the carrier substrate. 4. The recording medium according to claim A method according to claim 2, characterized in that the additional layer is a film attached at least to the edge of the carrier substrate. 5. A recording medium according to claim The process of claim 2, characterized in that the additional layer is a sheet of paper with an adhesive on one side. 6. A recording medium according to claim A method as claimed in claim 2, characterized in that the additional layer is a film of synthetic material with an adhesive on one side. 7. A recording medium according to claim 2, characterized in Fig. 1 Fig. 2 LZG Zakl. No. 3 in 8 in that the additional layer is a layer of lacquer sprayed onto the optical structure. 8. A recording medium according to claim The method of claim 1, characterized in that the optical structure comprises coplanar blocks of variable length separated by coplanar fields, both planes spaced a constant distance apart. 9. The recording medium according to claim 1, The method of claim 2, characterized in that in the additional layer, on the side thereof further away from the optical structure, a second optical structure reflecting the radiation in the direction opposite to the direction in which the radiation reflects the first optical structure and, furthermore, the second optical structure. An additional layer of substantially equal thickness is coated on the side farthest from the first optical structure. the carrier substrate. 10. The recording medium according to claim The method of claim 9, characterized in that the two optical structures contain the same video information encoded in different color television systems. 11. Apparatus for reading a record carrier on which information is recorded in an optical structure, comprising a radiation source emitting a reading beam, an objective focusing on the optical structure, and a radiation detection system for processing the read radiation beam. , modulated by the optical structure into an electrical signal, characterized in that it comprises means for obtaining a signal optically which is a measure of the deviation of the plane of the optical structure from the focus plane of the reading beam, which enables a proper adjusting the focus. 28 29 Fig. 3 Fig. 4 i. 654-76 on pages 115 + 20 copies and 10 zlotys